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| United States Patent |
5,646,665
|
|
Swanson
, et al.
|
July 8, 1997
|
Side biased datum scheme for inkjet cartridge and carriage
Abstract
An ink jet printer includes a movable carriage supported above an
ink-receiving medium by a rail defining a carriage axis, with a cartridge
holder mounted on said carriage having a plurality of cartridge
compartments each receiving a respective thermal ink jet printer
cartridge. Each cartridge is provided with three datum surfaces located on
the perimeter of a sidewall of the cartridge, and sufficiently spaced
apart from each other and from the center of gravity of the cartridge to
provide accurate and stable alignment. More particularly, the nozzle plate
of the cartridge is attached to a lower surface of snout portion such that
the Y axis of the nozzle plate is substantially parallel to the first
sidewall, with the first and second datum surfaces at the front and rear
of a lower end of the ink reservoir portion straddling the snout and the
third datum surface at an upper end of the ink reservoir portion. At least
the first and second datum surfaces are spaced from the Y axis within a
predetermined tolerance by a first predetermined spacing. The cartridge is
also provided with a forwardly facing fourth datum surface on a lower end
of the ink reservoir portion in front of the snout portion, and with a
downwardly facing fifth datum surface on the perimeter wall of the ink
reservoir portion adjacent the fourth datum surface and above said snout
portion, so as to establish a pivot axis above and in front of the snout,
and with a rearwardly facing sixth datum surface on an upper end of the
ink reservoir portion of said perimeter wall. The fourth datum surface is
spaced from the X axis of the nozzle plate within a predetermined
tolerance, while the locations of the fifth datum surface (which is used
to determine the spacing of the nozzle to the print medium) and the sixth
datum surfaces (which is used to determine angular orientation of the
cartridge about the pivot point) are somewhat less critical.
| Inventors:
|
Swanson; David W. (Escondido, CA);
Thoman; Jeffrey A. (San Diego, CA);
Rhoads; W. Wistar (Escondido, CA);
Marler; Jaren D. (Escondido, CA)
|
| Assignee:
|
Hewlett-Packard Company (Palo Alto, CA)
|
| Appl. No.:
|
057241 |
| Filed:
|
April 30, 1993 |
| Current U.S. Class: |
347/87 |
| Intern'l Class: |
B41J 002/175 |
| Field of Search: |
347/87
|
References Cited
U.S. Patent Documents
| 4709246 | Nov., 1987 | Piatt et al. | 347/87.
|
| 4709247 | Nov., 1987 | Piatt et al. | 347/86.
|
| 4755836 | Jul., 1988 | Ta et al. | 347/87.
|
| 4872026 | Oct., 1989 | Rasmussen et al. | 347/87.
|
| 4907018 | Mar., 1990 | Pinkerpell et al. | 347/87.
|
| 4998115 | Mar., 1991 | Nevarez et al. | 347/87.
|
| 5237342 | Aug., 1993 | Saikawa et al. | 347/87.
|
| 5278584 | Jan., 1994 | Keefe et al. | 347/87.
|
Primary Examiner: Lund; Valerie
Claims
What is claimed is:
1. In an inkjet printer comprising:
a movable carriage supported above an ink-receiving medium by a rail
defining a transverse printer axis;
a cartridge holder mounted on the cartridge and having a plurality of
cartridge compartments each spaced a predetermined transverse spacing from
an adjacent one of the cartridge compartments, each cartridge compartment
being separated from an adjacent compartment by a lateral compartment wall
perpendicular to the transverse printer axis;
a plurality of thermal ink jet printer cartridges each having a downwardly
facing nozzle plate, and a lateral cartridge wall perpendicular to the
nozzle plate, and
means for orienting the nozzle plate of each cartridge in a predetermined
orientation relative to the nozzle plates of the other cartridges,
including a predetermined vertical position, a predetermined side-to-side
position, a predetermined front-to-back position, a predetermined pitch
angle about a side-to-side axis, a predetermined yaw angle about a
vertical axis, and a predetermined roll angle about a front-to back axis,
wherein the nozzle plates are parallel to the print medium and spaced
therefrom by a predetermined vertical spacing, the side-to-side axes of
the cartridges are co-linear and parallel to the transverse axis of the
printer, and the front-to back axes of the cartridges are spaced apart
from each other by the predetermined transverse spacing;
the improvement wherein:
co-planar first, second, and third datum surfaces are defined on the same
lateral cartridge wall of each cartridge in predetermined positions above
and to one side of the nozzle plate to thereby form three vertices of a
triangle, with the first and second datum surfaces being disposed on a
lower portion of the cartridge below a predetermined center of gravity,
the first datum surface being disposed in front of the nozzle plate, the
second datum surface being disposed behind the nozzle plate, and the third
datum surface being disposed on an upper portion of the cartridge above
the center of gravity,
three co-planar supporting surfaces corresponding to the three co-planar
datum surfaces are defined on the same lateral compartment wall of each
compartment, with the corresponding datum surfaces in adjacent
compartments being transversely aligned and separated by the predetermined
transverse spacing, and
a lateral force is exerted on each cartridge to hold the three co-planar
datum surfaces against the three respective supporting surfaces,
whereby the three co-planar supporting surfaces cooperate with the three
co-planar datum surfaces to maintain the side-to-side axes parallel to the
transverse axis of the printer and the front-to back axes spaced apart
from each other by the predetermined transverse spacing.
2. The improvement of claim 1, wherein all the co-planar datum surfaces are
defined on a perimeter wall surrounding the lateral wall and the lateral
force includes a first component applied to the perimeter wall between the
first and second datum surfaces and a second component applied to the
perimeter wall adjacent the third datum surface.
3. The improvement of claim 1, wherein
each of the cartridges further comprises
a fourth datum surface on a intermediate vertical plane perpendicular to
the front-to-back cartridge axis and intersecting the lateral cartridge
wall between the first and second datum surfaces, the first vertical plane
being disposed in front of the nozzle plate and spaced from the
side-to-side cartridge axis by a front-to-back spacing, the fourth datum
surface being disposed above the nozzle plate and below the center of
gravity,
a fifth datum surface on a horizontal plane parallel to the side-to-side
axis and to the front-to-back axis and between the fourth datum surface
and the center of gravity, and
a sixth datum surfaces on a mar vertical plane parallel to the intermediate
vertical plane and perpendicular to the horizontal plane, the sixth datum
surface being disposed above the center of gravity adjacent the third
datum surface,
each of the compartments is provided with fourth, fifth and sixth
respective supporting surfaces corresponding to the fourth, fifth and
sixth datum surfaces of each respective cartridge,
a back-to-front force component is exerted on the lower portion of each
cartridge to hold the fourth datum surfaces of each of the cartridges
against the fourth supporting surfaces of the respective cartridge
compartment, to thereby maintain the predetermined front-to back position,
a downwards force component is exerted on each cartridge to hold the fifth
datum surfaces of each of the cartridges against the fifth supporting
surfaces of the respective cartridge compartment, to thereby maintain the
vertical position, and
a front-to back force component is exerted on an upper portion of each
cartridge to hold the sixth datum surface of each of the cartridges
against the sixth supporting surface of the respective cartridge
compartment, which cooperates with the back-to-front force component
holding the fourth datum surface against the fourth supporting surface to
maintain the predetermined pitch angle of the cartridge.
4. The improvement of claim 1, wherein all the side-to-side axes are
co-linear, all the intermediate vertical planes lie in a common
intermediate vertical plane, all the rear vertical planes lie in a common
rear vertical plane, and all the horizontal planes lie in a common
horizontal plane.
5. The printer of claim the improvement of claim 3, wherein the respective
nozzles of all of the cartridges are straddled by front and rear feed
rollers to maintain a print medium in a taut condition as the print medium
passes under the nozzles, one of the feed rollers being disposed between a
lower surface of the carriage below the fifth supporting surface and an
upper surface of the print medium adjacent the nozzle plates.
6. The printer of claim the improvement of claim 3, wherein
the fourth and fifth supporting surfaces cooperate with the fourth and
fifth datum surfaces to define a pivot axis parallel to the traverse
printer axis and in front of and above the nozzle plate.
7. The printer of claim the improvement of claim 6, wherein
an external vertical force is exerted on each of the cartridges adjacent to
the respective sixth datum surface which produces a torque about the pivot
axis which in turn results in the front-to-back force component being
exerted on upper portion of the cartridge.
8. The printer of claim the improvement of claim 7, wherein:
each the cartridge includes a respective electrical interface disposed on
the rear vertical plane adjacent the nozzle plate, and
the rear-to-front force is applied against the electrical interface.
9. A thermal ink jet printer cartridge having
a downwardly facing nozzle plate disposed on a first horizontal plane,
a lateral wall on one side of the nozzle plate and perpendicular to the
first horizontal plane,
co-planar first, second and third datum surfaces defined on the same
lateral cartridge wall of each cartridge in predetermined positions above
and to one side of the nozzle plate to thereby form three vertices of a
triangle, with the first and second datum surfaces being disposed on a
lower portion of the cartridge below a predetermined center of gravity,
the first datum surface being disposed in front of the nozzle plate, the
second datum surface being disposed behind the nozzle plate, and the third
datum surface being disposed on an upper portion of the cartridge above
the center of gravity,
a fourth datum surface on a first vertical plane intersecting the lateral
cartridge wall between the first and second datum surfaces in front of the
nozzle plate, the fourth datum surface being disposed above the nozzle
plate and below the center of gravity,
a fifth datum surface on a second horizontal plane above the first
horizontal plane and located between the fourth datum surface and the
center of gravity, and
a sixth datum surfaces on a second vertical plane behind the first vertical
plane, the sixth datum surface being disposed above the center of gravity
and adjacent the third datum surface.
10. The cartridge of claim 9 further comprising
a perimeter wall intersecting the lateral wall at an outer perimeter of the
cartridge,
wherein the co-planar first, second and third datum surfaces are defined on
the perimeter wall at the outer perimeter of the lateral wall.
11. The cartridge of claim 9 wherein the intersection of the first vertical
plane and the second horizontal plane defines a cartridge pivot axis in
front of and above the nozzle plate.
12. The cartridge of claim 9, wherein:
each cartridge includes a rearwardly facing electrical interface disposed
on the second vertical plane adjacent the nozzle plate.
Description
TECHNICAL FIELD
The present invention relates generally to inkjet printers having multiple
printing cartridges each having its own nozzle assembly and ink reservoir,
and more particularly to a cartridge datum scheme for ensuring accurate
and stable alignment of the cartridges when installed in a printer having
a multiple compartment cartridge holder.
CROSS-REFERENCE TO RELATED APPLICATIONS
For a more comprehensive view of what is presently regarded as the best
mode of practicing the invention and its intended environment, reference
should be made to the following commonly assigned U.S. patent applications
(and the patents and patent applications referenced therein):
J. Thoman et al, "Datum Machining & Structure", filed concurrently herewith
(Attorney Docket No. HP 1092629-1); and
D. W. Swanson et al, "Thin Pen Structure for Thermal Ink-jet Printer", U.S.
Ser. No. 07/994,809 filed 22 Dec. 1992 (Attorney Docket HP 1092607-1).
In addition, the following commonly assigned U.S. patent application claims
an invention which, although believed to be patentably distinguishable,
may be related to the present invention:
W. W. Rhoads, "Spring Cartridge Clamp for Inkjet Printer Carriage", filed
concurrently herewith (Attorney Docket HP 1093061-1)
and accordingly, is also hereby incorporated by reference.
BACKGROUND ART
From U.S. Pat. No. 4,755,836 it is known to provide an inkjet printer with
a pair of replaceable printing cartridges (each having at least one nozzle
assembly and associated ink reservoir) mounted on a common carriage, and
to maintain registration between the cartridges and the carriage by means
of alignment and registration features such as protuberances, shims,
opening and surfaces. A latch mechanism provides a loading force in all
three coordinate axes and cooperates with the registration and alignment
features to prevent pitch, yaw and roll of the cartridge.
That prior art registration and latching system was designed for use with
two relatively wide cartridges (one containing three colors of ink, each
in a separate ink reservoir and applied by a separate set of ink nozzles),
and located all the alignment and registration feature in the vicinity of
the nozzle plate assembly. Because it was relatively wide and short, the
prior art cartridge could be maintained in a predetermined spatial
orientation within reasonable limits without imposing exceedingly tight
tolerances on the locations of the various alignment and registrations
features, and had sufficient stability to maintain the cartridge in that
predetermined spatial orientation, even when subjected to sideways
inertial forces when the carriage was accelerated or decelerated; however,
especially if used with more than two cartridges, the prior art design
would result in a printer having a wide footprint, and is not readily
adaptable for use with four relatively tall and narrow cartridges.
From U.S. Pat. No. 4,872,026 it is known to facilitate the installation of
a single inkier cartridge by providing a lower pivot below an electrical
interface, adjacent the intersection of the contact and nozzle planes,
with the cartridge being held in its installed position by an upper latch
spring. Although that design is intended to provide some wiping action
between the electrical contacts as the cartridge is loaded into position,
such wiping is relatively minimal because of the close proximity of the
pivot point to the contact plane. Moreover, because the pivot of the prior
art design had to cooperate with a corresponding supporting structure on
the carriage, it was not possible to include any mechanism for tensioning
the ink receiving media in the immediate vicinity of the nozzle, thereby
exacerbating any tendency of the media to buckle and requiring a greater
than optimum spacing from the nozzle.
U.S. Pat. No. 4,709,247 discloses a non-mechanical alignment and
registration scheme for a multiple cartridge inkjet printer which
automatically measures alignment errors in a test pattern and computes
corresponding data adjustments to be used in a subsequent printing
operation.
SUMMARY OF THE INVENTION
In accordance with one overall aspect of the present invention, an ink jet
printer includes a movable carriage supported above an ink-receiving
medium by a rail defining a carriage axis, with a cartridge holder mounted
on said carriage having a plurality of cartridge compartments each
receiving a respective thermal ink jet printer cartridge; each cartridge
includes a respective nozzle plate, and three datum surfaces on the side
of each of the cartridges cooperate with respective supporting surfaces on
a sidewall of its respective compartment, to maintain the cartridges
parallel to each other with a predetermined spacing between the Y axes on
each respective nozzle when a sideways bias force is applied to each
cartridge.
In accordance with other more specific aspects, each of the cartridges are
provided with three additional datum surfaces, including adjacent
horizontal and vertical datum surfaces above the snout of the cartridge,
which cooperate with corresponding supporting surfaces defined in a bottom
wall of its the respective compartment to maintain the required spacing
between the nozzle plate and the ink receiving media below the carriage
and to align the respective nozzles relative to a common X axis, and a
sixth datum surface located at the upper rear of the cartridge. The
cartridge is installed by pushing it into its compartment with a natural
downward motion until the horizontal datum surface contacts the
corresponding supporting surface on the bottom of the cartridge
compartment, and then rotating the cartridge rearwardly about a pivot
point defined by the intersection of the horizontal and vertical datum
surfaces with a natural rearward motion until the sixth datum surface
contacts the corresponding supporting surfaces on the rear of the
cartridge compartment. Because the pivot axis is located above and in
front of the snout, the electrical interface at the lower rear of the
cartridge moves downwards as the cartridge is rotated rearwardly about the
pivot access during installation, thereby providing an enhanced
self-cleaning wiping action between the electrical contact surfaces on the
cartridge and the cartridge holder.
In accordance with a second overall aspect of the invention, a cartridge
for a ink jet printer is provided with three datum surfaces located on the
perimeter of a sidewall of the cartridge, and sufficiently spaced apart
from each other and from the center of gravity of the cartridge to provide
accurate and stable alignment. More particularly, the nozzle plate of the
cartridge is attached to a lower surface of snout portion such that the Y
axis of the nozzle plate is substantially parallel to the first sidewall,
with the first and second datum surfaces at the front and rear of a lower
end of the ink reservoir portion straddling the snout and the third datum
surface at an upper end of the ink reservoir portion. At least the first
and second datum surfaces are spaced from the Y axis within a
predetermined tolerance by a first predetermined spacing.
In accordance with still other more specific aspects, the cartridge is also
provided with a forwardly facing fourth datum surface on a lower end of
the ink reservoir portion in front of the snout portion, a downwardly
facing datum surface on the perimeter wall of the ink reservoir portion
adjacent the fourth datum surface and above said snout portion so as to
establish a pivot axis above and in front of the snout, and a rearwardly
facing sixth datum surface on an upper end of the ink reservoir portion of
said perimeter wall. The fourth datum surface is spaced from the X axis of
the nozzle plate within a predetermined tolerance, while the locations of
the fifth datum surface (which is used to determine the spacing of the
nozzle to the print medium) and the sixth datum surfaces (which is used to
determine angular orientation of the cartridge about the pivot point) are
somewhat less critical. The cartridge also preferably includes a
reenforcing bracket for supporting the fourth datum surface which is
integrally formed in said perimeter wall at a juncture of a downwardly
facing surface of the ink reservoir portion and a forwardly facing portion
of the snout portion.
BRIEF DESCRIPTION OF THE DRAWINGS
Other objects and features of the present invention will be apparent from
the following description of a presently preferred embodiment taken in
connection with the accompanying drawings, in which:
FIG. 1 is an isometric view showing the major components of an inkjet
printer incorporating the present invention.
FIG. 2 comprising FIGS. 2A, 2B, and 2C are isometric views showing one of
printer "cartridges" of FIG. 1 being inserted into a corresponding slot of
the cartridge holder;
FIG. 3 comprising FIGS. 3A and 3B are isometric views of the cartridge of
FIG. 2 as seen from the top rear and bottom front, respectively, and show
the six "datum" surfaces provided in the cartridge, as well as the various
registration forces which are applied to the cartridge to maintain these
surfaces against corresponding registration features provided in the
cartridge holder;
FIG. 4 is a side view, partly in cross section, of the cartridge and a
corresponding portion of the cartridge holder, and illustrates the wiping
action of their respective electrical contacts as the cartridge is
inserted in the cartridge holder;
FIG. 5 is another side view, partly in cross section, showing the cartridge
and a corresponding portion of the cartridge holder with their respective
contacts engaged to thereby provide a registration force in the Y axis,
and also showing the snout of the cartridge in its operational position
relative to an advancing sheet of print media;
FIG. 6 is an exploded isometric view of the cartridge holder and the
various springs which hold the cartridges with their respective datum
surfaces in contact with the respective registration features provided in
each compartment of the cartridge holder;
FIG. 7 is a side view, partly in cross section, of the upper rear portion
of the cartridge and cartridge holder, showing the cam of the latching
spring in contact with a corresponding lip at the top of the cartridge to
thereby provide a compound registration force having components in the X
and Z axes;
FIG. 8 is a rear view, partly in cross section, taken along line 8--8 of
FIG. 7, and shows the two force components produced by the latch spring;
FIG. 9 is a front view, partly in cross section, of respective occupied and
empty compartments of the cartridge holder, showing how a relatively thin
cantilevered leaf spring provides a sideways bias force in the X axis at
the lower end of the cartridge without adding unnecessary width to the
cartridge holder; and
FIG. 10 comprising FIGS. 10A and 10B are respective side and front views of
the leaf spring of FIG. 9.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
FIG. 1 shows a small footprint, high quality inkjet printer 10
incorporating the present invention. In particular, inkjet printer 10
includes a movable carriage 12 supported on a rail 14. As best shown in
FIG. 2C, movable carriage 12 includes a cartridge holder 16 provided with
a plurality of individual cartridge compartments 18 for receiving a
respective plurality of thermal ink jet printer cartridges 20. Inkjet
printer 10 also is provided with input tray 22 containing a number of
sheets of bond paper or other suitable ink-receiving medium 24, and an
upper output tray 26 for receiving the printed media. As best shown in
FIG. 5, each cartridge 20 is supported above the ink-receiving medium 24
by the cartridge holder 16, such that a nozzle plate 30 on lower surface
32 (FIG. 3B) is maintained an appropriate distance 34 from ink-receiving
medium 24. As is conventional in inkjet printers, inkjet printer 10 is
also provided with feed rollers 36 which maintain the print medium 24 in a
taut condition as it passes under the nozzle plate 30, and which advance
ink-receiving medium 24 in a direction 38 perpendicular to the carriage
axis defined by rail 14.
Referring now to FIG. 2, comprising FIGS. 2A, 2B, and 2C, it will be seen
that cartridge 20 is installed by pushing it into its cartridge
compartment 18 with a natural downward motion D until its horizontal datum
surface 40 (see FIGS. 4 and 5) contacts the corresponding supporting
surface 42 on the bottom of the cartridge compartment 18, and then
rotating the cartridge 20 rearwardly (FIG. 2C) about a pivot point P (FIG.
5) in the vicinity of the intersection of the horizontal and vertical
datum surfaces 40, 44 (FIG. 5) with a natural rearward motion R until an
upper datum surface 46 (FIG. 4) contacts a corresponding supporting
surface 48 on the upper rear of the cartridge compartment. As shown in
FIG. 2A, cartridges 20 are preferably provided with a protective strip 50
which is removed prior to installation to expose the contact surface of an
electrical interface 52 carried on rear surface of cartridges 20, as well
as nozzle plate 30 (FIG. 3).
Reference should now be made to FIG. 3 (comprising FIGS. 3A and 3B, which
are isometric views of cartridges 20 as seen from the top rear and bottom
front, respectively), which shows the three side-biased "datum" surfaces
provided in the cartridge in addition to the above-mentioned datum
surfaces 40, 44, 46, namely, three datum surfaces 54, 56, 58 on one side
of cartridge 20, which cooperate to define an Y-Z orientation plane
substantially perpendicular to the nozzle plane defined by nozzle plate 30
and substantially parallel to its Y axis. It will also be noted that
vertical datum surface 44 is defined on a reenforcing bracket 62
integrally formed in the perimeter wall 64 of cartridge 20 at a juncture
66 of a downwardly facing surface 68 of the ink reservoir portion 70 and a
forwardly facing portion 72 of the snout portion 74.
FIG. 3 also shows the various registration forces which when applied to the
cartridge 20, serve to maintain these surfaces against corresponding
registration features provided in the cartridge holder, namely a first
sideways force X1 applied in the +X direction to the lower part of ink
reservoir 70, a forward force Y applied in the +Y direction in the
vicinity of electrical interface 52, and a third force F applied in the
vicinity of upper rear datum surface 46 and upper side datum surface 58
and having a sideways component X2 in the +X direction and a downwards
component Z in the -Z direction (see FIG. 8). It should be noted that the
three side-biased datum surfaces 54, 56, 58 are located on the edge of the
perimeter wall 64 of the cartridge 20, thereby providing additional
rigidity and positional accuracy relative to the X axis, and are spaced
apart from each other in the form of a triangle which surrounds the center
of gravity CG of the cartridge, thereby facilitating a more accurate and
stable alignment. Furthermore, since the downwards component Z of force F
is offset horizontally in the +Y direction from horizontal datum surface
40 and associated supporting surface 42, the resultant counterforce from
supporting surface 42 generates a net torque T which rotates cartridge 20
about pivot axis P, thereby forcing upper rear datum surface 46 into
contact with sixth supporting surface 48. Because the pivot axis P (FIG.
5) is located above and in front of the snout 74, the electrical interface
52 at the lower rear of the cartridge 20 moves downwards as the cartridge
is rotated rearwardly about the pivot axis P during installation, thereby
producing an enhanced self-cleaning wiping action between the electrical
contact surfaces on the cartridge and the cartridge holder. Moreover, even
if force F has a relatively small component in the X direction, because it
is at least as far above the center of gravity CG as is the center of
gravity above the fulcrum defined by the two lower datum surfaces 54, 56,
that relatively small force component will still suffice to prevent the
cartridge from tipping sideways from an inertial force of more than twice
its magnitude; in an exemplary embodiment, the mass of cartridge 20 is
about 115 g and the maximum acceleration of movable carriage 12 is 1.5 g,
which would require a force X2 (assuming zero friction) of about 1.75N,
compared to an actual value (again assuming zero friction) of about 2.5N.
Of the various datum surfaces and their corresponding supporting surfaces,
it should be understood that the most critical tolerances are associated
with the two lower side-facing datum surfaces 54, 56 (which ensure that Y
axes of the respective nozzle plates are parallel and accurately spaced
apart) and with the lower vertical datum surface 44 (which ensures that
all the X axes of the nozzle plates are aligned). In an exemplary
embodiment, the cartridge 20 has a nominal height (not including snout
portion 74) of 78 mm, a depth of 60 mm and a width of 19.18 mm; the
nominal center-to-center spacing of the nozzle Y axes (and thus of the
cartridges 20 and compartments 18) is 23.241 mm. High quality 4 color
printing is obtained when each of the supporting surfaces 84, 86 is held
to a tolerance of .+-.0.025 mm from its nominal spacing to the
corresponding surface of an adjacent compartment 18 and the alignment of
the three critical supporting surfaces 45, 84, 86 on cartridge holder 16
is such that they do not deviate more than .+-.0.0125 mm from a respective
X-Z or Y-Z plane, and when the corresponding datum surfaces 44, 54, 56 of
cartridge 20 do not deviate from the respective X-Z or Y-Z plane defined
by the nozzle X and Y nozzle axes by more than .+-.0.020 mm.
FIG. 6 is an exploded isometric view of the cartridge holder 16 and the
various springs which hold the cartridges with their respective datum
surfaces in contact with the respective registration features provided in
each compartment of the cartridge holder. In particular it will be seen
that a downwardly projected cantilevered leaf spring 78 is attached to a
sidewall 80 of each cartridge compartment 18 opposite the sidewall 82
(FIG. 9) carrying the three supporting surfaces 84, 86, 88 corresponding
to the three datum surfaces 54, 56, 58 (see FIG. 9), which provides the
first sideways force X1. Leaf spring 78 is preferably manufactured from
spring steel (for example 1050 steel) having a low friction
corrosion-resistant coating (for example nickel), to minimize frictional
forces between the surface of the spring and the lower edge of cartridge
20 opposite lower datum surfaces 54, 56, which otherwise would generate a
countertorque about an axis defined by lower datum surfaces 54, 56 tending
to oppose the sideways component X2 and might thus prevent cartridge 20
from assuming its desired orientation relative to the Y-Z plane defined by
the three supporting surfaces 84, 86, and 88. As can best be seen in FIGS.
10A and 10B, which comprise respective side and front views of the leaf
spring 78, in its uncompressed condition the main portion of leaf spring
78 does not lie flat against sidewall 80, but extends into the interior of
compartment 18 at an angle of about 71/2.degree. and has a precision bend
90 of about 12.degree. to thereby approximating a circular arc when
uncompressed and, when fully compressed, a straight line parallel to
sidewall 80 with lower end 92 in contact with the lower end of ink
reservoir portion. Leaf spring 78 thus is capable of providing a
substantial sideways bias force X1 of approximately 13N at the desired
location without adding substantial width to the cartridge holder 16.
The upper portion of FIG. 6 shows a latch assembly 94 for securing all four
cartridges 20 inside their respective cartridge compartments 18 of
cartridge holder 16. Latch assembly 94 comprises a metallic spring 96
stamped from full hard stainless steel, and comprises four forwardly
facing latch ends 98 separated by five respective forwardly facing
supporting ends 100. Preferably, each latch end 98 is connected to its two
adjacent supporting ends 100 by a serpentine arm 102 defined by suitable
radiused cutouts in stamped spring 96 to provide a shape that approximates
a constant stress geometry. Each supporting end 100 is terminated by
straight edge 104 which is inserted into a corresponding slot 106 (FIG. 7)
at the upper rear of cartridge holder 16; because latch assembly 94 is a
single unit, only one assembly operation is required for all four
cartridge compartments 18. Because of the serpentine shape of the
individual serpentine arm 102, it is possible to provide a spring that is
relatively compact from front to rear and yet provides a relatively
substantial constant force (of approximately 17.3N) over a relatively
large deflection range. This compactness contributes in turn to the
overall compactness of cartridge holder 16 and thus of inkjet printer 10.
Each latch end 98 is provided with a cam 108 preferably molded of a low
friction material such as PTFE filled acetal (in the ratio of 20% PTFE,
80% acetal), which has a coefficient of friction substantially lower than
the coefficient of friction of the stainless steel component of the
spring. As shown in FIGS. 6, 7 and 8, each molded cam 108 is shaped in the
form of a horizontal section of an inclined, sideways oriented cylinder
(ie, a cylinder having its axis parallel to the X axis and tilted about
the Y axis). As is best shown in FIG. 8, a lower tangential plane formed
by the cylindrical surface intersects the plane of the latch end 98 at an
oblique angle of about 15.6.degree., which is complementary to a
corresponding oblique surface 112 of a reenforced lip 114 formed on
perimeter wall 64 of cartridge 20 between upper rear datum surface 46 and
upper side datum surface 58, thereby producing the sideways component X2
of force F, with the low coefficient of the molded plastic material
resulting in a greater net sideways force X2 for a given force F.
When a cartridge 20 is inserted into the cartridge compartment 18 (see also
FIGS. 2 and 4) the low coefficient of friction of molded cam 108 permits
it to slip over oblique surface 112. Thereupon, serpentine arm 102 exerts
a downward force Z and sideways force X2 which through the curved surface
onto the cartridge. The downward Z force presses the cartridge 20 downward
onto the carriage until it contacts horizontal supporting surface 42,
while force Y (11N in an exemplary embodiment) produced by electrical
interface 52 presses vertical datum surface 44 against vertical supporting
surface 45. As noted previously, since the downwards component Z of force
F is offset horizontally in the +Y direction from horizontal datum surface
40 and associated supporting surface 42, the resultant counterforce from
supporting surface 42 generates a net torque T (FIG. 7) which rotates
cartridges 20 about pivot axis P, thereby forcing upper rear datum surface
46 into contact with sixth supporting surface 48, while the sideways bias
force X2 presses upper side datum surface 58 against upper side supporting
surface 88 (FIG. 8).
It is understood that the above-described embodiment is merely provided to
illustrate the principles of the present invention, and that other
embodiments may readily be devised using these principles by those skilled
in the art without departing from the scope and spirit of the invention.
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